Measurements using the inelasticity distribution of multi-TeV neutrino   interactions in IceCube

IceCube Collaboration: M. G. Aartsen; M. Ackermann; J. Adams; J. A.; Aguilar; M. Ahlers; M. Ahrens; I. Al Samarai; D. Altmann; K. Andeen; T.; Anderson; I. Ansseau; G. Anton; C. Arg\"uelles; J. Auffenberg; S. Axani; P.; Backes; H. Bagherpour; X. Bai; A. Barbano; J. P. Barron; S. W. Barwick; V.; Baum; R. Bay; J. J. Beatty; J. Becker Tjus; K.-H. Becker; S. BenZvi; D.; Berley; E. Bernardini; D. Z. Besson; G. Binder; D. Bindig; E. Blaufuss; S.; Blot; C. Bohm; M. B\"orner; F. Bos; S. B\"oser; O. Botner; E. Bourbeau; J.; Bourbeau; F. Bradascio; J. Braun; M. Brenzke; H.-P. Bretz; S. Bron; J.; Brostean-Kaiser; A. Burgman; R. S. Busse; T. Carver; E. Cheung; D. Chirkin,; K. Clark; L. Classen; G. H. Collin; J. M. Conrad; P. Coppin; P. Correa; D. F.; Cowen; R. Cross; P. Dave; M. Day; J. P. A. M. de Andr\'e; C. De Clercq; J. J.; DeLaunay; H. Dembinski; K. Deoskar; S. De Ridder; P. Desiati; K. D. de Vries,; G. de Wasseige; M. de With; T. DeYoung; J. C. D\'iaz-V\'elez; V. di Lorenzo,; H. Dujmovic; J. P. Dumm; M. Dunkman; E. Dvorak; B. Eberhardt; T. Ehrhardt; B.; Eichmann; P. Eller; P. A. Evenson; S. Fahey; A. R. Fazely; J. Felde; K.; Filimonov; C. Finley; A. Franckowiak; E. Friedman; A. Fritz; T. K. Gaisser,; J. Gallagher; E. Ganster; S. Garrappa; L. Gerhardt; K. Ghorbani; W. Giang; T.; Glauch; T. Gl\"usenkamp; A. Goldschmidt; J. G. Gonzalez; D. Grant; Z.; Griffith; C. Haack; A. Hallgren; L. Halve; F. Halzen; K. Hanson; D. Hebecker,; D. Heereman; K. Helbing; R. Hellauer; S. Hickford; J. Hignight; G. C. Hill,; K. D. Hoffman; R. Hoffmann; T. Hoinka; B. Hokanson-Fasig; K. Hoshina; F.; Huang; M. Huber; K. Hultqvist; M. H\"unnefeld; R. Hussain; S. In; N. Iovine,; A. Ishihara; E. Jacobi; G. S. Japaridze; M. Jeong; K. Jero; B. J. P. Jones,; P. Kalaczynski; W. Kang; A. Kappes; D. Kappesser; T. Karg; A. Karle; U. Katz,; M. Kauer; A. Keivani; J. L. Kelley; A. Kheirandish; J. Kim; T. Kintscher; J.; Kiryluk; T. Kittler; S. R. Klein; R. Koirala; H. Kolanoski; L. K\"opke; C.; Kopper; S. Kopper; J. P. Koschinsky; D. J. Koskinen; M. Kowalski; K. Krings,; M. Kroll; G. Kr\"uckl; S. Kunwar; N. Kurahashi; A. Kyriacou; M. Labare; J. L.; Lanfranchi; M. J. Larson; F. Lauber; K. Leonard; M. Leuermann; Q. R. Liu; E.; Lohfink; C. J. Lozano Mariscal; L. Lu; J. L\"unemann; W. Luszczak; J. Madsen,; G. Maggi; K. B. M. Mahn; Y. Makino; S. Mancina; I. C. Mari\c{s}; R. Maruyama,; K. Mase; R. Maunu; K. Meagher; M. Medici; M. Meier; T. Menne; G. Merino; T.; Meures; S. Miarecki; J. Micallef; G. Moment\'e; T. Montaruli; R. W. Moore; M.; Moulai; R. Nagai; R. Nahnhauer; P. Nakarmi; U. Naumann; G. Neer; H.; Niederhausen; S. C. Nowicki; D. R. Nygren; A. Obertacke Pollmann; A. Olivas,; A. O'Murchadha; E. O'Sullivan; T. Palczewski; H. Pandya; D. V. Pankova; P.; Peiffer; J. A. Pepper; C. P\'erez de los Heros; D. Pieloth; E. Pinat; A.; Pizzuto; M. Plum; P. B. Price; G. T. Przybylski; C. Raab; M. Rameez; L.; Rauch; K. Rawlins; I. C. Rea; R. Reimann; B. Relethford; G. Renzi; E.; Resconi; W. Rhode; M. Richman; S. Robertson; M. Rongen; C. Rott; T. Ruhe; D.; Ryckbosch; D. Rysewyk; I. Safa; S. E. Sanchez Herrera; A. Sandrock; J.; Sandroos; M. Santander; S. Sarkar; S. Sarkar; K. Satalecka; M. Schaufel; P.; Schlunder; T. Schmidt; A. Schneider; J. Schneider; S. Sch\"oneberg; L.; Schumacher; S. Sclafani; D. Seckel; S. Seunarine; J. Soedingrekso; D. Soldin,; M. Song; G. M. Spiczak; C. Spiering; J. Stachurska; M. Stamatikos; T. Stanev,; A. Stasik; R. Stein; J. Stettner; A. Steuer; T. Stezelberger; R. G. Stokstad,; A. St\"o{\ss}l; N. L. Strotjohann; T. Stuttard; G. W. Sullivan; M.; Sutherland; I. Taboada; F. Tenholt; S. Ter-Antonyan; A. Terliuk; S. Tilav; P.; A. Toale; M. N. Tobin; C. T\"onnis; S. Toscano; D. Tosi; M. Tselengidou; C.; F. Tung; A. Turcati; C. F. Turley; B. Ty; E. Unger; M. A. Unland Elorrieta,; M. Usner; J. Vandenbroucke; W. Van Driessche; D. van Eijk; N. van Eijndhoven,; S. Vanheule; J. van Santen; M. Vraeghe; C. Walck; A. Wallace; M. Wallraff; F.; D. Wandler; N. Wandkowsky; T. B. Watson; A. Waza; C. Weaver; M. J. Weiss; C.; Wendt; J. Werthebach; S. Westerhoff; B. J. Whelan; N. Whitehorn; K. Wiebe; C.; H. Wiebusch; L. Wille; D. R. Williams; L. Wills; M. Wolf; J. Wood; T. R.; Wood; E. Woolsey; K. Woschnagg; G. Wrede; D. L. Xu; X. W. Xu; Y. Xu; J. P.; Yanez; G. Yodh; S. Yoshida; T. Yuan

arXiv:1808.07629·hep-ex·February 26, 2019

Measurements using the inelasticity distribution of multi-TeV neutrino interactions in IceCube

IceCube Collaboration: M. G. Aartsen, M. Ackermann, J. Adams, J. A., Aguilar, M. Ahlers, M. Ahrens, I. Al Samarai, D. Altmann, K. Andeen, T., Anderson, I. Ansseau, G. Anton, C. Arg\"uelles, J. Auffenberg, S. Axani, P., Backes, H. Bagherpour, X. Bai, A. Barbano, J. P. Barron

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TL;DR

This paper measures the inelasticity distribution of multi-TeV neutrino interactions in IceCube, providing insights into neutrino fluxes, flavor composition, and charm production, and testing Standard Model predictions at high energies.

Contribution

It introduces a method to reconstruct inelasticity in IceCube and applies it to 5 years of data, offering new constraints on neutrino fluxes, flavor ratios, and charm production at TeV-PeV energies.

Findings

01

Inelasticity distribution matches theoretical calculations across 1-100 TeV.

02

Power-law spectrum with index 2.62±0.07 describes astrophysical neutrinos.

03

Limits on neutrino flavor composition and charm production are established.

Abstract

Inelasticity--the fraction of a neutrino's energy transferred to hadrons--is a quantity of interest in the study of astrophysical and atmospheric neutrino interactions at multi-TeV energies with IceCube. In this work, a sample of contained neutrino interactions in IceCube is obtained from 5 years of data and classified as 2650 tracks and 965 cascades. Tracks arise predominantly from charged-current $ν_{μ}$ interactions, and we demonstrate that we can reconstruct their energy and inelasticity. The inelasticity distribution is found to be consistent with the calculation of Cooper-Sarkar et al. across the energy range from $\sim$ 1 TeV to $\sim$ 100 TeV. Along with cascades from neutrinos of all flavors, we also perform a fit over the energy, zenith angle, and inelasticity distribution to characterize the flux of astrophysical and atmospheric neutrinos. The energy spectrum of diffuse…

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